活性流体和剪切软玻璃态材料的有效温度。

Effective temperature of active fluids and sheared soft glassy materials.

作者信息

Nandi Saroj Kumar, Gov N S

机构信息

Department of Chemical and Biological Physics, The Weizmann Institute of Science, 76100, Rehovot, Israel.

出版信息

Eur Phys J E Soft Matter. 2018 Oct 11;41(10):117. doi: 10.1140/epje/i2018-11731-7.

DOI:10.1140/epje/i2018-11731-7

PMID:30302578

Abstract

The dynamics within active fluids, driven by internal activity of the self-propelled particles, is a subject of intense study in non-equilibrium physics. These systems have been explored using simulations, where the motion of a passive tracer particle is followed. Similar studies have been carried out for a soft glassy material that is driven by shearing its boundaries. In both types of systems the non-equilibrium motion have been quantified by defining a set of "effective temperatures", using both the tracer particle kinetic energy and the fluctuation-dissipation relation. We demonstrate that these effective temperatures extracted from the many-body simulations fit analytical expressions that are obtained for a single active particle inside a visco-elastic fluid. This result provides testable predictions and suggests a unified description for the dynamics inside active systems.

摘要

由自推进粒子的内部活性驱动的活性流体中的动力学，是非平衡物理学中深入研究的一个主题。已经通过模拟对这些系统进行了探索，其中追踪了被动示踪粒子的运动。对于通过剪切其边界驱动的软玻璃材料也进行了类似的研究。在这两种类型的系统中，通过使用示踪粒子动能和涨落耗散关系定义一组“有效温度”，对非平衡运动进行了量化。我们证明，从多体模拟中提取的这些有效温度符合为粘弹性流体中单个活性粒子获得的解析表达式。这一结果提供了可检验的预测，并为活性系统内部的动力学提出了统一的描述。

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活性流体和剪切软玻璃态材料的有效温度。

Effective temperature of active fluids and sheared soft glassy materials.

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